Optimization of a Simple Ammonia−Water Absorption Refrigeration Cycle by Application of Mixed-Integer Nonlinear Programming

Chávez-Islas, Luz María; Heard, C.L.

doi:10.1021/ie800828w

Cited by 15 publications

(10 citation statements)

References 15 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Systematic methods based on mathematical techniques have been utilized for optimization of absorption cycle [54,89,90]. However, the literature has gap since the approaches have focused on either the absorption cycle or the solar system.…”

Section: Optimization Analysismentioning

confidence: 99%

Review and recent improvements of solar sorption cooling systems

Bataineh

Taamneh

2016

Energy and Buildings

View full text Add to dashboard Cite

Section: Optimization Analysismentioning

confidence: 99%

Review and recent improvements of solar sorption cooling systems

Bataineh

Taamneh

2016

Energy and Buildings

View full text Add to dashboard Cite

“…The evaporator and the reboiler also have no choice with regard to the type of heat exchanger and, thus, their discontinuous capital cost functions are the same as in previous work. 2 Process Scheme Synthesis for Case 1. In case 1, for both scenarios, it can be seen that the pressure drop on the vapor side of the plate frame heat exchanger for refrigerant subcooling is greater than that established for the mass and energy balances, which implies the elimination of this option for this unit.…”

Section: Corrugated Tubes (Itcc)mentioning

confidence: 99%

Synthesis and Optimization of an Ammonia−Water Absorption Refrigeration Cycle Considering Different Types of Heat Exchangers by Application of Mixed-Integer Nonlinear Programming

Chávez-Islas

Heard

Grossmann

2009

Ind. Eng. Chem. Res.

Self Cite

View full text Add to dashboard Cite

Optimization of the operating conditions and process scheme of an ammonia−water absorption refrigeration system, minimizing operating and annualized capital costs, is described. Various heat-exchanger technologies, the effect of the evaporator purge, and the thermodynamic restrictions of the system are taken into account. The objective is to make optimum use of various heat-exchange technologies to reduce the capital cost and meet the process refrigeration service requirements. A procedure to take account of the film coefficients and pressure drops of the different types of heat exchangers considered is proposed, which gives a solid basis for making decisions regarding the use of industrial ammonia−water absorption refrigeration.

show abstract

“…To reduce the anthropogenic GHGE and the harmful climate change effects caused by them, several governments around the world have implemented incentive policies, such as carbon tax credits and subsidies, for stimulating the investment in clean and renewable energy related technologies to increase their deployment. In this context, Chavez‐Islas et al proposed an approach for designing ammonia‐water AR systems, while Florides et al modeled an absorption solar cooling system, Assilzadeh et al introduced a methodology for a solar cooling system using evacuated tube solar collectors and LiBr absorption unit, Lecuona et al determined the optimal hot water temperature that maximizes the efficiency of a chiller, Fathi et al studied the effect of the variables that affect the coefficient of performance ( COP ) of absorption refrigerators and Wu et al presented optimization formulations for designing AR systems. Additionally, mathematical programming approaches have been proposed to design energy systems (i.e., Savola and Fogelholm et al presented a MINLP model for increasing the power production in small scale; Tveit et al proposed a MINLP model for analyzing new investments and operation of CHP plants and Hamed et al carried out the optimization of an absorption refrigerator in dynamic mode).…”

Section: Introductionmentioning

confidence: 99%

Optimum heat storage design for solar‐driven absorption refrigerators integrated with heat exchanger networks

et al. 2013

View full text Add to dashboard Cite

A methodology is presented for optimizing hybrid renewable energy-fossil fuel systems with short-term heat storage. The considered system is an absorption-refrigeration (AR) cycle integrated with a heat exchanger network (HEN) requiring cooling below ambient temperature. The AR cycle can be driven by multiple energy sources including excess energy from hot process streams, renewable energy sources (solar and biofuels), and fossil fuels. A two-step approach based on mixed integer nonlinear programming methods is used for the optimization. First, the problem of optimal energy integration in the hybrid energy system without heat storage is solved on a monthly basis by minimizing simultaneously the total annual cost and the overall greenhouse gas emissions. In the second step, the multi-tank thermal energy storage (TES) design problem is solved. The design involves the identification of the optimal number of storage tanks, their sizes, configuration and operation policies. The TES optimization is carried out on an hourly basis while incorporating the design targets determined by the first step. V C 2013 American Institute of Chemical Engineers AIChE J, 60: 909-930, 2014

show abstract

Optimization of a Simple Ammonia−Water Absorption Refrigeration Cycle by Application of Mixed-Integer Nonlinear Programming

Cited by 15 publications

References 15 publications

Review and recent improvements of solar sorption cooling systems

Review and recent improvements of solar sorption cooling systems

Synthesis and Optimization of an Ammonia−Water Absorption Refrigeration Cycle Considering Different Types of Heat Exchangers by Application of Mixed-Integer Nonlinear Programming

Optimum heat storage design for solar‐driven absorption refrigerators integrated with heat exchanger networks

Contact Info

Product

Resources

About